Технологические системы

  В другій частині статті розглядається алгоритм аналізу похибок, який враховує основні принципи теорії термофізичних експериментів та їх похибок, базується на засадах сучасного досвіду проведення експериментів з теплопереносу і падіння тиску у воді, що знаходиться в надкритичному стані, а також на попередньому досвіді проведення експериментів з теплопереносу в умовах до критичного тиску.

Kirillov, P.L., Pomet’ko, R.S., Smirnov et al., 2005. Experimental study on heat transfer to supercritical water flowing in vertical tubes, Proceedings of the International Conference GLOBAL-2005 “Nuclear Energy Systems for Future Generation and Global Sustainability”, Tsukuba, Japan, October 9–13, Paper No. 518, 8 pages.

Pis’mennyy, E.N., Razumovskiy, V.G., Maevskiy E.M. et al., 2005. Experimental study on temperature regimes to supercritical water flowing in vertical tubes at low mass fluxes, Proceedings of the International Conference GLOBAL-2005 “Nuclear Energy Systems for Future Generation and Global Sustainability”, Tsukuba, Japan, October 9–13, Paper No. 519, 9 pages.

Pioro, I.L. and Khartabil, H.F., 2005. Experimental study on heat transfer to supercritical carbon dioxide flowing upward in a vertical tube, Proceedings of the 13th International Conference on Nuclear Engineering

(ICONE-13), Beijing, China, May 16–20, Paper No. 50118, 9 pages.

Guo, Y., Bullock, D.E., Pioro, I.L. and Martin, J., 2006. Measurements of sheath temperature profiles in LVRF bundles under post-dryout heat transfer conditions in Freon, Proceedings of the 14th International Conference on Nuclear Engineering (ICONE-14), July 17–20, Miami, Florida, USA, Paper #89621, 9 pages.

Bezrodny, M.K., Pioro, I.L. and Kostyuk, T.O., 2005. Transfer Processes in Two-Phase Thermosyphon Systems. Theory and Practice, (In Russian), 2nd edition, Augmented and Revised, Fact Publ. House, Kiev,

Ukraine, 704 pages.

Leung, L.K.H., Pioro, I.L. and Bullock, D.E., 2003. Post-dryout surface-temperature distributions in a vertical freon-cooled 37-element bundle, Proceedigns of the 10th International Topical Meeting on Nuclear Reactor Thermal Hydraulics (NURETH-10), Seoul, Korea, October 5–9, Paper C00201, 13 pages.

Pioro, I.L., Groeneveld, D.C., Leung, L.K.H. et al., 2002a. Comparison of CHF measurements in horizontal and vertical tubes cooled with R-134a, International Journal of Heat and Mass Transfer, 45 (22), pp. 4435– 4450.

Pioro, I.L., Groeneveld, D.C., Doerffer, S.S. et al., 2002b. Effects of flow obstacles on the critical heat flux in a vertical tube cooled with upward flow of R-134a, International Journal of Heat and Mass Transfer, 45 (22), pp. 4417–4433.

Pioro, I.L., Groeneveld, D., Cheng, S.C. et al., 2001. Comparison of CHF measurements in R-134a cooled tubes and the water CHF look-up table, International Journal of Heat and Mass Transfer, 44 (1), pp. 73–88.

Pioro, I.L., Cheng, S.C., Vasiс, A. and Felisari, R., 2000. Some problems for bundle CHF prediction based on CHF measurements in simple flow geometries, Nuclear Engineering and Design, 201 (2–3), pp. 189–207.

Pioro I.L., 1999. Experimental evaluation of constants for the Rohsenow pool boiling correlation, International Journal of Heat and Mass Transfer, 42, pp. 2003–2013.

Pioro, I.L., 1992. Maximum heat-transferring capacity of two-phase thermosiphons with separate vapor and condensate streams, Heat Transfer Research, 24 (4), pp. 535–542.

Pioro, L.S. and Pioro, I.L., 1997. Industrial Two- Phase Thermosyphons, Begell House, New York, NY, USA, 288 pages.

Kichigin, A.M. and Pioro, I.L., 1992. Analysis of methods for detecting dryout and burnout fluxes, Heat Transfer Research, 24 (7), pp. 957–964.

Pioro, I.L. and Kalashnikov, A.Yu., 1988. Maximum heat transfer in two-phase thermosyphons with external down-flow channel, Applied Thermal Sciences, 1 (2), pp. 62–67.

Pioro, I.L., 1982. Investigation of closed twophase thermosyphons used for cooling of melting converters, (In Russian), Applied Problems of Heat Transfer and Hydrodynamics, Naukova Dumka, Publishing House, Kiev, Ukraine, pp. 76–79.

Coleman, H.W. and Steele, W.G., 1999. Experimentation and Uncertainty Analysis for Engineers, 2nd edition, J. Wiley & Sons, Inc., New York, USA, 275 pages.

Hardy, J.E., Hylton, J.O., McKnight, T.E. et al., 1999. Flow Measurement Methods and Applications. J. Wiley & Sons, Inc., New York, NY, USA, pp. 207–208.

Guide to the Expression of Uncertainty in Measurement, 1995. Corrected and Reprinted, International Bureau of Weights and Measures and other International Organizations, 101 pages.

Holman, J.P., 1994. Experimental Methods for Engineers, 6th edition, McGraw-Hill, Inc., New York, NY, USA, 616 pages.

Moffat, R.J., 1988. Describing the uncertainties in experimental results, Experimental Thermal and Fluid Science, 1, pp. 3–17.

Gortyshov, Yu.F., Dresvyannikov, F.N., Idiatullin, N.S. et al., 1985. Theory and Technique of Thermophysical Experiment, Textbook for Technical Universities, (In Russian), Editor V.K. Shchukin, Energoatomizdat Publishing House, Moscow, Russia, 360 pages.

Topping, J. 1971. Errors of Observation and Their Treatment, 3rd edition, Chapman and Hall Ltd., London, UK, 119 pages.

Mark’s Standard Handbook for Mechanical Engineers, 1996. Editors: Eu.A. Avallone and Th. Baumeister III, McGraw-Hill, New York, NY, USA, p. 16-2.

National Institute of Standards and Technology, 2010. NIST Reference Fluid Thermodynamic and Transport Properties-REFPROP. NIST Standard

Reference Database 23, Ver. 9.0. Boulder, CO, U.S.: Department of Commerce.

The Temperature Handbook, 2000. OMEGA Engineering, Inc., 21st Century Edition, Vol. MM.

White, F.M., 1994. Fluid Mechanics. Third edition, McGraw-Hill, Inc., New York, NY, USA, pp. 364–365.

The Flow and Level Handbook, 2000. OMEGA Engineering, Inc., 21st Century Edition, Vol. MM, (Transactions, Vol. 4, p. 22).

Pioro, I., Zvorykina A., 2012. Some important aspects for experimental papers: Part 1. Typical heattransfer / thermalhydraulics test facility and practical recommendations for performing experiments, Technological Systems (Ukraine), Vol. 1 (58). P. 17–28. ISSN 2074-0603.